Simulating real-world terrain on an exercise device

ABSTRACT

A system may include a receiving module and a conversion module. The receiving module may be for receiving location data associating video data depicting a real-world route with topographical location of the real-world route. The conversion module may be for creating an exercise program. The exercise program could include control signals representing changes to be made to one or more operating parameters of an exercise device as the video data depicting the real-world route is displayed to a user of the exercise device. The control signals may be based at least in part on the location data. The changes to the one or more operating parameters may correspond at least in part to one or more aspects of the real-world route.

RELATED APPLICATIONS

This application claims priority to provisional patent application No. 62/126,268 titled “Simulating Real-World Terrain on an Exercise Device” filed Feb. 27, 2015, which application is herein incorporated by reference for all that it discloses.

BACKGROUND

Field

Embodiments discussed herein generally relate to simulating real-world terrain on an exercise device. In particular, some embodiments may relate to simulating real-world terrain associated with video data of a real-world route.

Relevant Technology

Finding motivation to use an exercise device on a consistent and ongoing basis is a common challenge for users of exercise devices. The repetitive nature of exercise routines that a user performs on a particular exercise device may act to limit the motivation of the user.

With typical exercise devices, a user may remain in a relatively limited area during the exercise routine. To provide diversity during the exercise routine, the user's level of exertion may be varied at various times during the exercise routine. Providing variety to the user's level of exertion may often be insufficient to motivate the user to use the exercise device on an ongoing basis.

A lack of mental stimulation experienced by the user during the exercise routine may also act to limit the user's motivation. Users may grow bored with their unchanging surroundings. Many users may listen to music and/or watch television to help relieve their boredom, but if the user is sufficiently engaged by the music and/or the television to avoid boredom, the user's exercise intensity often suffers, which may reduce the benefit of the exercise routine.

Furthermore, many exercise devices are equipped with a display to provide visual stimulation and motivation to the user of the device. For example, some displays depict a track for indicating to a user how far the user has run, pedaled, or the like. Similarly, some displays depict hills that provide a visual representation of the resistance or inclination of the device. While these types of displays may provide some visual stimulation to the user, most users will quickly become bored with such displays, and the desired stimulatory benefits will not be realized. In contrast, when a person goes outside for a walk, run, or bicycle ride, the person's surrounding are constantly changing, which can provide sufficient mental stimulation to keep the person motivated throughout the exercise routine.

The claimed subject matter is not limited to embodiments that solve any disadvantages or that operate only in environments such as those described above. Rather, this background is only provided to illustrate one exemplary area in which some of the described embodiments may be practiced.

SUMMARY

Embodiments may relate to systems, methods, and devices for creating and distributing exercise programs. These exercise programs may be for prompting selective adjustment of an exercise device and/or to simulate real-world terrain associated with video data of a real-world route. Physical simulation of real-world terrain and displaying video depicting the real-world route for a user of an exercise device may provide the user with greater interest and motivation to use the exercise device. The simulation and the video may further provide a real sense of what it is like to traverse the terrain of the real-world route. In some instances, video data captured during a particular event, such as a race, may further provide a sense of what it is like to participate in the real-life event. In some instances, environmental conditions may be included in the simulation of the real-world terrain and/or the real-life event.

This Summary introduces a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential characteristics of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

In an aspect of the disclosure, a system may include a receiving module and a conversion module. The receiving module may be for receiving location data associating video data depicting a real-world route with a topographical, geographical and/or environmental location of the real-world route. The conversion module may be for creating an exercise program including control signals representing changes to be made to one or more operating parameters of an exercise device as the video data depicting the real-world route is displayed to a user of the exercise device. The control signals may be based at least in part on the location data. The changes to the one or more operating parameters may correspond at least in part to one or more aspects of the real-world route.

Another aspect of the disclosure may include any combination of the above-mentioned features and the receiving module may be further for receiving the video data depicting the real-world route.

Yet another aspect of the disclosure may include any combination of the above-mentioned features and the conversion module may be further for stabilizing the video data depicting the real-world route.

Still yet another aspect of the disclosure may include any combination of the above-mentioned features and the exercise program may further include the video data depicting the real-world route stabilized by the conversion module.

A further aspect of the disclosure may include any combination of the above-mentioned features and the location data may include global positioning data collected via a satellite navigation system as the video data captures the real-world route.

Yet another further aspect of the disclosure may include any combination of the above-mentioned features and the exercise program may further include environment signals representing one or more target environmental parameters for a location of the exercise device, the target environment parameters may correspond at least in part to one or more aspects of the real-world route.

Another aspect of the disclosure may include any combination of the above-mentioned features and the one or more target environmental parameters may include time-dependent environmental parameters.

Yet another aspect of the disclosure may include any combination of the above-mentioned features and the receiving module may be further for receiving time data, and the one or more target environmental parameters may include a time-dependent environmental parameter corresponding at least in part to one or more aspects of the real-world route estimated to occur at a time associated with the time data.

Still yet another aspect of the disclosure may include any combination of the above-mentioned features and the exercise program may further include perceived route data representing at least a portion of the real-world route as perceived via the video data, where an icon overlaying the video data and located on the perceived route is depicted as being located on the real-world route depicted by the video data.

A further aspect of the disclosure may include any combination of the above-mentioned features and the system may be for sending ghost data representing a first icon that moves along the perceived route defined by the perceived route data to appear to move along the real-world route depicted by the video data.

Yet another further aspect of the disclosure may include any combination of the above-mentioned features and may further include a computing device including the receiving module and the conversion module.

Still yet another further aspect of the disclosure may include any combination of the above-mentioned features and may further include a communication device including the receiving module and the conversion module, the communication device may be for delivering the exercise program to the exercise device by way of a network.

Another aspect of the disclosure may include any combination of the above-mentioned features and may further include a distribution module for providing, by way of the network, information about a plurality of exercise programs the communication device may deliver to the exercise device. The distribution module may be further for delivering the exercise program to the exercise device by way of the network in response to the exercise program being selected from the plurality of exercise programs.

Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include the exercise device including the receiving module and the conversion module.

Additional features and advantages will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the embodiments. The features and advantages of the embodiments will be realized and obtained by means of the instruments and combinations particularly pointed out in the claims. These and other features will become more fully apparent from the following description and claims, or may be learned by the practice of the embodiments as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

To further clarify the above and other advantages and features of the present disclosure, a more particular description will be rendered by reference to specific embodiments thereof, which are illustrated in the appended drawings. These drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1 is a diagram of an example exercise system;

FIG. 2 is a diagram of an example exercise program creator that may be employed in the example exercise system of FIG. 1;

FIG. 3 is a representation of a person participating in an activity with example route data capturing devices that may be employed in the example exercise system of FIG. 1; and

FIG. 4 is a representation of an example frame of video data that may be displayed in the example exercise system of FIG. 1.

DETAILED DESCRIPTION

The system may include creating and distributing exercise programs simulating real-world terrain on exercise devices. The real-world terrain of the exercise programs may be associated with video data of a real-world route. In some instances, the exercise program may include the video data. Alternately, the video data may be separate from the exercise program. The video data may be captured by personal video-capturing devices accompanying a person traversing the real-world route. Thus, the video data of the real-world route may closely represent what a person would see when traversing the real-world route.

Location data associating the video data with a topographical, geographical and/or environmental location of the real-world route may be used to create the exercise programs and the exercise programs may include control signals that cause the exercise equipment to change various operating parameters as the exercise program is executed. The location data may be captured by personal location-capturing devices accompanying the person traversing the real-world route. In some instances, a single device may capture both the video data and the location data as the person traverses the real-world route. Alternately or additionally, the location data may be captured by a device separate from the video-capturing device. Alternately or additionally, the location data may be input by a user, such as by identifying a path of the real-life route in a map program.

Optionally, the exercise program may include environment signals that cause the exercise equipment to change various environmental parameters of the location of the exercise device. The environment signals may be based on environment data related to the real-world route. In some instances, the environment data may be captured by the location-capturing device, the video-capturing device, and/or other devices accompanying the person traversing the real-world route. Alternatively or additionally, the environment data may be based on observed or estimated environment data, including forecasted environment data.

Optionally, the exercise program may include perceived route data associating the real-world route with the video data. The perceived route data may permit the exercise device to introduce supplementary visual data to the video data to depict the supplementary visual data as being located on the real-world route. In some instances, supplementary visual data may be introduced to indicate the upcoming path of the real-world route, particularly where the real-world route does not follow a clearly-defined path such as a road or trail. Alternately or additionally, supplementary visual data such as an icon may be introduced to indicate the relative position of one or more signposts and/or “ghosts” for purposes such as information, racing, pacing, motivation, or the like or any combination thereof. In some instances, the exercise device may receive data related to the relative position of one or more ghosts corresponding to the rate at which other users completed or are completing the exercise program. By way of example, two or more users of the exercise program may participate in a virtual race over the same simulated real-world route, even in instances where the two or more users complete the exercise program at different times and/or in different locations or environments. In some instances, ghost data and/or other supplementary visual data in conjunction with the video data depicting the real-world route may act to further keep a user both motivated and exercising at a high intensity.

When a user executes a particular exercise program in connection with an exercise device, the user may exercise while the video data depicting the real-world route is displayed to the user. The rate at which the video data is displayed to the user may generally correspond to a rate at which the user would traverse the real-world route with the effort exerted while using the exercise device. The operating parameters of the exercise device may change to simulate the real-world terrain corresponding to the video data. Thus, the user executing the exercise program via the exercise device may experience a simulated navigation of the real-world route. Depending upon factors such as the fitness level of the user, the operating parameters of the exercise device may also be more or less challenging than the corresponding real-world terrain. This may, for example, facilitate training for a particular event or activity. This may also allow users of different fitness levels and/or abilities to perform all or a portion of a given activity.

For example, where the video data was captured while traversing an inclined real-world route, the exercise device may change one or more operating parameters to provide the user with a sensation of traversing a similarly inclined route. For instance, the exercise device may change one or more operating parameters of the exercise device, such as an incline/decline, a tilt, a speed, a resistance, or the like, or any combination thereof.

In instances where the exercise program includes environment signals, the exercise device may change one or more environmental conditions of the location of the exercise device, such as a room housing the exercise device and/or a space near the user of the exercise device. The environment data may further simulate the real-world route by changing one or more of the environmental conditions experienced by the user of the exercise device based on one or more environmental conditions of the real-world route. In some instances, the environmental signals may be based on the environmental conditions of the real-world route as observed or estimated to exist at the time the video data was captured. Alternately, the environmental signals may be based on environmental conditions observed or estimated to exist at a different time. For example, an exercise program intended to facilitate training for a particular race may include environment signals based on environmental conditions likely to exist at the scheduled time of the particular race.

The system may allow users to browse and/or search a collection of available exercise programs and to select an exercise program from the collection. A selected exercise program may be sent to an exercise device of the selecting user. The system may provide relevant information regarding the exercise programs to allow users to identify exercise programs that meet desired criteria.

By way of example, a runner, cyclist, hiker, cross-country skier, or the like may traverse a real-world terrain with a video-capturing device positioned to capture video data of the real-world route. Traversal of the real-world terrain may be associated with a race or some other event, such as a marathon or the like. Location data and/or environment data may also be captured by the video-capturing device, some other device, and/or by a user inputting location regarding the real-world route.

The system may receive the location data, the environment data and/or the video and may create one or more exercise programs to include in the collection of available exercise programs. Optionally, the system may stabilize or otherwise alter the video data. Incentives may be provided to encourage users and/or other parties to provide data that will lead to the creation of popular exercise programs. Thus, the system may facilitate the creation of a rich collection of exercise programs covering a variety of races, events, routes, terrains, locales, and/or the like.

In some embodiments, the system may allow a user to select variables independently. For example, a user may plot a course on an interactive map, may select one or more videos associated with the selected course or with portions of the selected course, and/or may select environmental conditions. Thus, for example, a user may select a course not precisely associated with a particular video, and/or may select conditions different from those associated with the selected video or videos. For instance, a user may wish to train in more extreme conditions or in more comfortable conditions than are associated with the selected video or videos.

Reference will now be made to the figures wherein like structures will be provided with like reference designations. The drawings are diagrammatic and schematic representations of exemplary embodiments and, accordingly, are not limiting of the scope of the claimed subject matter, nor are the drawings necessarily drawn to scale. The system may include one or more features and/or aspects shown in the drawings, or combinations thereof. The system may also be used in combination with other features and/or aspects depending, for example, upon the intended use of the system.

FIG. 1 is a diagram of an example exercise system 100. The exercise system 100 may include an example exercise device 104 contained within a location 102. The location 102 may be a room containing the exercise device 104, an unbound area surrounding the exercise device, or the like.

The exercise device 104 may include any form of controllable exercise machine, including treadmills, stationary cycles, Nordic-style skiers, rowers, steppers, hikers, climbers, elliptical or striding devices, or the like.

The exercise device 104 may include operating mechanics 110. The operating mechanics 110 may include one or more electrically-driven or other mechanisms for creating or otherwise controlling movement. Operating mechanics may include motors, actuators, and the like for controlling one or more operating parameters of the exercise device 104, such as speed, resistance, incline (e.g., front-to-back incline/decline), tilt (e.g., side-to-side tilt), or the like.

The exercise device 104 may further include a controller 108 for controlling the operating parameters of the exercise device via the operating mechanics 110. Optionally, the controller 108 may control environmental parameters of the location 102 via an environment control 116.

In some embodiments, the environment control 116 may form part of the exercise device 104. Alternately, the environment control 116 may be physically separate from the exercise device 104 and may be communicatively coupled with or connected to the exercise device. Operation of the environment control 116 may generally be similar to the environment controller described in United States Patent Application Publication No. 2013/0267383, which is incorporated by reference in its entirety.

The environment control 116 may include a communication module 120 for communicating with one or more environment-altering devices 118. The environment-altering devices 118 may include any devices for altering an environment of the location 102. The environment-altering devices 118 may include home-automation devices associated with the location 102, devices built into the exercise device 104, and/or separate devices associated with the location. Environment-altering devices 118 may include heating/cooling systems, humidifiers, dehumidifiers, fans, misters, lighting, or the like or any combination thereof.

The environment control 116 may include a learning module 124. The learning module 124 may consider the effects of the environment-altering devices 118, the exercise device 104, the user of the exercise device 104, weather conditions, and/or the like on the environmental conditions of the location 102. For example, the learning module 124 may monitor one or more environmental conditions of the location 102 via sensors 122, and/or via querying one or more of the environment-altering devices 118. The learning module 124 may further monitor one or more operating parameters of the exercise device 104, the environment-altering devices 118, the user, or the like. Operating parameters of the user may include the user's heart rate, work output, or the like. In some embodiments, the learning module 124 may monitor the weather in a geographical location associated with the location 102 to consider the effects of weather on the environmental conditions of the location 102. The learning module 124 may retrieve weather conditions from one or more of the environment-altering devices 118, the sensors 122, resource systems 130 via a network 127, or the like. For example, the learning module 124 may retrieve weather conditions via a website such as WEATHER.COM, WEATHER.GOV, ACCUWEATHER.COM, or the like.

The learning module 124 may generally determine a model for how the environmental conditions of the location 102 are affected by various parameters and may control the environment-altering devices 118 according to the model to allow environmental parameters indicated by the exercise programs to be more accurately obtained. The learning module 124 may employ machine learning or a similar method for determining how the environmental conditions of the location 102 are affected by various parameters.

The learning module 124 may predict and/or account for delays between changing an operating parameter of one or more of the environment-altering devices 118 and obtaining a desired environmental condition of the location 102. By way of example, if the exercise device 104 is located in a small room with unobstructed heating and cooling vents, it may not take long for the environmental condition of the small room to change after changing an operating parameter of an associated heating or cooling system. Conversely, if the exercise device 104 is located in a large room with few unobstructed heating or cooling vents, it may take more time for the environmental conditions to change after changing the operating parameter of the associated heating or cooling system.

Similarly, the intensity at which the user of the exercise device 104 is exercising may affect the environmental conditions of the location 102. For example, the user may raise the temperature and/or humidity of a small room relatively quickly during and immediately following periods of high-intensity exercise. The user may have less of an effect on the environmental conditions of the location 102 if the exercise device 104 is in a large room.

The learning module 124 may allow environmental parameters associated with various exercise programs to be more accurately achieved with minimal hassle from the user of the exercise device 104. Put another way, learning module 124 may allow environment signals of the exercise program to prompt desired changes to the environmental conditions of the location 102 without being particularly adapted for individual exercise devices in various settings. Thus, in some instances, the experience of executing a particular exercise program may be made consistent across different settings.

The operating parameters of the exercise device 104 and/or the environmental parameters of the location 102 may be changed by a user of the exercise device 104 and/or by an exercise program.

In some embodiments, the exercise program may be located in a storage device 114 of the exercise device 104 and executed by a processor 115 of the exercise device 104. Alternately or additionally, the exercise program may be located in a storage device (not shown) external to the exercise device 104. The storage external to the exercise device 104 may be communicatively coupled with or connected to the exercise device 104 via the communication module 112.

The communication module may allow communication between the example exercise device 104 and other parts of the exercise system 100, including the environment control 116, a video display device 106, a network 127, a computing device 126, and/or route data capturing devices 128. The communication module 112 may optionally receive exercise programs from the computing device 126 and/or from the network 127. The communication module 112 may communicate via a variety of connections, including wired connections; wireless connections such as IEEE 802.11 wireless communication connections, BLUETOOTH, and/or infrared (IR); physical insertion of portable storage devices such as universal serial bus (USB) flash drives, secure digital (SD) memory cards; or the like or any combination thereof.

The exercise system 100 may include the video display device 106. In some embodiments, the video display device 106 may form part of the exercise device 104 or may otherwise be physically attached to the exercise device 104. Alternately, the video display device 106 may be physically separate from the exercise device 104 and may be communicatively coupled with or connected to the exercise device 104 or may otherwise be for displaying video data associated with the exercise program. In some embodiments, multiple video display devices (not shown) generally corresponding to the video display device 106 may be included in the exercise system 100.

The exercise system 100 may include one or more exercise program creators such as an exercise program creator 134A, an exercise program creator 134B, and an exercise program creator 134C (which may be collectively or individually referred to as “exercise program creators 134” for convenience and brevity). By way of example, the exercise device 104 may include the exercise program creator 134A. Alternately or additionally, the computing device 126, which may be a desktop computer, laptop computer, tablet computer, mobile phone, or the like, may include the exercise program creator 134B. Alternately or additionally, the communication device 132, such as a server accessible over the network 127 via a website, an application, or the like, may include the exercise program creator 134C.

The exercise program creators 134 may accept data from one or more route data capturing devices 128 to create the exercise program.

FIG. 2 is a diagram of an example exercise program creator 200 that may generally correspond to the exercise program creators 134 of FIG. 1. Although the exercise program creator 200 is illustrated as having discrete modules, in some instances the various modules may be combined into fewer modules, divided into additional modules, and/or removed based on the desired implementation.

The exercise program creator 200 may include a receiving module 202. The receiving module 202 may receive location data associating video data depicting a real-world route with a topographical, geographical or environmental location of the real-world route. The location data may include and/or may allow derivation of a relative speed at which the video data depicts the real-world route, elevations of the real-world route, changes of elevation of the real-world route, a latitude and longitude of the real-world route, or the like or any combination thereof.

Optionally, in some embodiments, the receiving module 202 may also receive the video data depicting the real-world route. The location data, however, may be employed to create the exercise program separate of the video data. For example, in some instances, the location data may be used to create an exercise program that may be paired with the associated, but separate, video data. In some instances, creating the exercise program without the video data may allow exercise programs to be created without extensive transmission of video data files, which may be relatively large, particularly when the video data was captured over a particularly long period of time.

FIG. 3 is an exemplary representation of a person 302 participating in an activity with example route data capturing devices that may generally correspond to the route data capturing devices 128 of FIG. 1.

The person 302 may wear, carry or otherwise use a video data capturing device 304 while participating in an activity. The person 302 is shown as running, but the activity may alternatively or additionally include cycling, skiing, walking, hiking, or the like. The video data capturing device 304 is shown as being worn on a torso of the person 302, but the video data capturing device 304 may alternately be worn on a head or other body part of the person 302, or may be attached to equipment, such as a frame of a bicycle, associated with the activity.

The video data capturing device 304 may capture location data in addition to video data. Alternately or additionally, a location data capturing device 306 may capture location data. The location data capturing device 306 may include sensors including, for example, a GPS receiver, a compass, accelerometers, gyroscopes, timekeepers, or the like or any combination thereof. The location data capturing device 306 may include a mobile phone, a running watch, a cycling computer, or the like or any combination thereof. In some embodiments, the video data capturing device 304, the location data capturing device 306, and/or a separate environment data capturing device (not shown) such as a portable environment monitor may capture environment data.

With combined reference again to FIG. 1 and FIG. 2, in some embodiments, the video data and the location data may be located within the same data file. For example, the video data and the location data may be captured by a single device. In some instances, the location data may be exported or otherwise separated from the data file containing the video data. Alternatively or additionally, at least some of the location data may be captured by a device separate from the device that captured the video data. The video data and the location data captured by separate devices may be synchronized by time values and/or other data shared between the video data and the location data. Alternately or additionally, the synchronization may be done manually.

In some embodiments, the location data may be used to query information not included in or derivable from the location data, and/or information more detailed than the information included in or derivable from the location data. For example, if elevation data is not included or derivable for one or more portions of the real-world route, the exercise program creator 200 may request elevation data from the resource systems 130 based on other data such as latitude and longitude data from the location data. In some instances, elevation data and/or other location data may be queried from a third-party resource system 130 such as MAPQUEST.COM, MAP.GOOGLE.COM, the GOOGLE EARTH database, the Global 30 Arc-Second Elevation (GTOPO30) database, the BING MAPS database, the APPLE MAPS database, the United States Geological Survey (NSGS) National Elevation Dataset (NED) database, or the like or any combination thereof. In some embodiments, the location data associated with the video data may be identified via the resource systems 130. For example, a user may identify a route within one or more of the resource systems 130 defining the real-world route.

In some embodiments, the location data may include global positioning data collected via a satellite navigation system. For example, the location data may include Global Positioning System (GPS) data, Global Navigation Satellite System (GLONASS) data, Galileo data, or the like. The location data may be in a variety of formats, such as GPS Exchange (GPX) format, Extensible Markup Language (XML) format, or the like. In some embodiments, the location data format may be converted to one or more particular formats for use in creating the exercise program.

The exercise program creator 200 may include a conversion module 204. The conversion module 204 may create the exercise program based on the location data. In some embodiments, the conversion module 204 may alternately or additionally create the exercise program based on the video data and/or environment data.

The control signals may represent changes to be made to one or more operating parameters of the exercise device 104. The conversion module 204 may create the control signals based on one or more aspects of the real-world route. For example, the control signals may represent changes to be made to the incline of the exercise device 104. The control signals may be based on a pitch of the terrain corresponding to the perspective of the video data and the control signals may be used by the operating mechanics 110. For example, for video data that is captured while running up a path having a 7-degree pitch, the control signals may correspond to a positive 7-degree pitch operating parameter of the exercise device 104. By further example, for video data that is captured while traveling 10 miles per hour, the control signals may correspond to a 10 mile per hour speed operating parameter of the exercise device 104. In some embodiments, the control signals may be specific to a particular type or class of exercise device, such as a treadmill or a stationary cycle. The exercise program may include control signals specific to a variety of classes and/or types of exercise devices.

Alternately or additionally, the control signals may be generic to two or more classes of exercise devices. In some instances, different classes of exercise devices may change different operating parameters and/or may change the same operating parameters to different degrees in response to the same control signals. The response to the control signals may be based on changing the operating parameters that may most realistically simulate the real-world terrain corresponding to the control signals. For example, a treadmill may change an incline operating parameter based on incline-based control signals and a stationary cycle may change a resistance operating parameter based on the incline-based control signals. By way of further example, an elliptical device change an incline operating parameter to a different degree than the treadmill and may also change a resistance operating parameter to a different degree than the stationary cycle based on the incline-based control signals.

In some instances, the control signals may be altered to reflect operating limitations, safety regulations, and/or safety limitations of the exercise device 104. For example, if the pitch of the terrain is outside of an incline range of the exercise device 104, the control signals may be restricted to a particular range. Furthermore, if the pitch of the terrain changes faster or more often than is recommended for a tilt-controlling motor and/or actuator, the control signals may be filtered in a manner that keeps to exercise device 104 within recommended operating conditions. By way of still further example, if the pitch changes suddenly without advance visual warning from the video data, e.g., if the path takes a sharp, sudden turn from a flat path to stairs or some other steep pitch, the control signals may slow the degree of change of the incline to allow a user of the exercise program time to recognize that the incline is to change. In some embodiments, a smoothing factor may be applied to the control signals to encourage the rate at which operating conditions of the exercise device 104 change to remain within a particular range. The smoothing factor may be dependent on the type of exercise device 104. For example, a treadmill may employ a smoothing factor, a different style of treadmill may employ another smoothing factor, an exercise bicycle may employ another smoothing factor, and/or an elliptical device may employ another smoothing factor.

In some embodiments, the conversion module 204 may further create indicator signals representing information to be displayed by the video display device 106 of the and/or by a non-video display device (not shown) of the exercise device 104. The indicator signals may represent information related to the real-world route. For example, the indicator signals may include a percentage of the exercise program finished, a distance traveled, a distance to go, and/or a total distance of the real-world route, or the like or any combination thereof.

In some embodiments, the conversion module 204 may be for stabilizing the video data. In some instances, the video data may be captured in a way that causes the video data to shake, bounce, sway, or otherwise move in a manner that may make the video data detract from the sensation that a user of the exercise program is traversing the terrain shown in the video data. Furthermore, in some instances, observing video data that moves in a manner inconsistent with an observer's sensation of movement may cause motion sickness in some people, sometimes described as simulation sickness. The conversion module 204 may stabilize the video data. Alternately or additionally, resource systems 130 such as third-party video-processing systems may be used to stabilize the video data. In some instances, the conversion module 204 may employ location data and/or other data accompanying the video data, e.g., gyroscope information from a video capture device, in stabilizing the video data.

The rate at which the video data is displayed on the video display device 106 may generally correspond to a rate at which the user would traverse the real-world route given the amount of work output by the user at the example exercise device 104. The exercise programs may allow a user to observe the video data at the rate the video data was captured, but fitness levels and/or training goals of the user, or the like may have the user traversing one or more portions of the simulated real-world route of the exercise program faster or slower than the video data was captured. The video data may be displayed at a correspondingly faster or slower rate to match the user's simulated location.

In some embodiments, the exercise program may include environmental signals representing target environmental parameters. The target environmental parameters may correspond to aspects of the real-world route. For example, the environmental parameters may include temperatures, humidities, wind speeds, wind directions, light values such as color and intensity, or the like of the real-world route. The target environmental parameters may be based on environment data observed as the video data was captured.

Alternately or additionally, the receiving module 202 may receive time data. In some instances, the time data may indicate the time the video data and/or the location data was captured and may be included in the location data and/or the video data. The time data may be used to retrieve estimated and/or observed weather conditions present at the real-world route at the time the video data was captured via a website such as WEATHER.COM, WEATHER.GOV, ACCUWEATHER.COM, or the like. Alternately or additionally, the time data may indicate a time different from the time the video data and/or the location data was captured. Estimated, average, and/or forecasted weather conditions at the real-world route may be retrieved via a website or the like for the different time.

In some embodiments, one or more of the target environmental parameters may be time-dependent. By way of example, a temperature-based environmental parameter may be based on the real-world route generally warming or cooling as the day goes on, and/or may be based on a weather event such as a cold front coming in at a particular time. In some embodiments, time-dependent environmental parameters of the exercise program may occur at a particular time into the exercise program regardless of where a user of the exercise program is located along the simulation of the real-world route. Such time-dependent environmental parameters may allow for a more realistic simulation of traversing the real-world route, as traversing the real-world route faster would not cause the day to warm or cool faster.

In some embodiments, one or more of the target environmental parameters may be route-dependent. By way of example, a light-based environmental parameter may be based on the video depicting shaded areas of the real-world route, sunny areas of the real-world route, and the like. Such route-dependent environmental parameters may allow for a more realistic simulation of the video data and the real-world route, as the environmental parameters may change to reflect what a user of the exercise program sees on the video data as well as what the user would see if traversing the real-world route at the given pace.

In some instances, time-dependent environmental parameters may be based on aspects of the real-world route that a user of the exercise program may not observe in the video data. Route-dependent environmental parameters may be based on aspects of the real-world route that the user of the exercise program may observe in the video data. In some embodiments, the route-dependent environmental parameters may be relative to the time-dependent environmental parameters. For example, a route-dependent environmental parameter may increase or decrease the time-dependent environmental parameters by a particular number of degrees, by an amount defined by a formula, or the like. Defining the route-dependent environmental parameters relative to the time-dependent environmental parameters may allow for a more realistic simulation of the real-world route, as localized effects of the real-world route, such as traversing a shaded area, may affect time-dependent environmental parameters, such as an overall temperature.

The exercise program creator 200 may include a distribution module 208. The distribution module 208 may be used to allow users to browse, select, and/or receive exercise programs. In some instances, the exercise program creator 134C may include the distribution module 208 to allow the created exercise programs to be delivered to a variety of users (not shown) and/or exercise devices (not shown). The exercise program creator 134C and/or the distribution module 208 may be analogous, similar or related to the exercise device 104 by way of the network 127.

In some embodiments, the distribution module 208 may include a website and/or other internet-based system for allowing users to browse and/or search a collection of available exercise programs. By way of example, the distribution module 208 may be included in the IFIT® system (IFIT is a registered trademark of ICON Health & Fitness, Inc.). For example, exercise programs may be distributed at WWW.IFIT.COM/FITNESSSHOP and/or via exercise equipment otherwise connected to the IFIT fitness shop via the network 127.

The distribution module 208 may further allow users to rate and/or review exercise programs the users have tried. In some embodiments, the distribution module 208 may allow users or other third parties to upload video data and location data to allow the exercise program creator 200 to create an exercise program as described herein for use by the uploading user and/or for distribution on the website. Alternately or additionally, the distribution module 208 may allow users to upload exercise programs for distribution. For example, the distribution module 208 may allow exercise programs created by the exercise program creator 134A or the exercise program creator 134B to be uploaded.

The distribution module 208 may be for encouraging users to upload high-quality, unique, and/or varied video data, location data, and/or exercise programs. For example, the distribution module 208 may rank uploaders, data and/or exercise programs according to the popularity, ratings, and/or the like. Alternately or additionally, the distribution module 208 may create a competitive atmosphere for the uploaders. Alternately or additionally, the distribution module 208 may provide compensation in the form of money, credits to be used for product (e.g., exercise programs) from the distribution module 208, or the like.

The distribution module 208 may provide information about the characteristics of the available exercise programs. The exercise programs may be searched, filtered, ranked, or the like according to the characteristics of the exercise programs. By way of example, characteristics of the exercise programs may include total distance, maximum and/or minimum incline values, elevation changes, what types of environmental parameters are included (if any), maximum and/or minimum temperature values or other environmental parameter values, compatibility with particular types of exercise devices, video quality, video stabilization, time of day, event type (e.g., marathon, century cycling race, steeplechase, or the like), ratings by other users, uploader identity, or the like or any combination thereof.

Optionally, the exercise program may include perceived route data representing the real-world route as perceived via the video data. In some embodiments, the conversion module 204 may generate the perceived route data. Alternately or additionally, one or more resource systems 130 such as third-party video processing systems may be used to generate the perceived route data. The perceived route data may allow the exercise device 104 to overlay the video data with supplementary visual data such as depictions of the perceived route. Alternately or additionally, the exercise device 104 may overlay the video data with other supplementary visual data such as one or more icons located on the perceived route. The user of the exercise program may perceive the icons as being located on and following the real-world route depicted by the video data.

In some embodiments, the perceived route data may be generated without the video data. For example, the location data, such as GPS data, compass data, accelerometer data, gyroscope data, or the like or any suitable combination thereof may be used to generate the perceived route data in a manner analogous to generating overlay placement in augmented reality techniques, although other suitable techniques may be used.

In some instances, information about the characteristics of the video data may be considered in generating the perceived route data. For example, information regarding a field of view, a focal length, a frame size, or the like of the video data associated with the location data may be used to create the perceived route data for the exercise program. In some instances, the perceived route data may be abstracted relative to the characteristics of the video data to allow the exercise device 104 to adapt the perceived route data to match the characteristics of the video data.

Alternatively or additionally, the video data may be used in generating the perceived route data. For example, the video data may be analyzed, with or without the location data, to generate the perceived route data in a manner analogous to cinematographic match moving techniques, also described as motion tracking or camera solving, although other suitable techniques may be used.

FIG. 4 is a representation of an example frame 400 of video data that may be displayed by the video display device 106 of the exercise system 100 of FIG. 1. Perceived route data for the video data including the frame 400 may be included in an associated exercise program.

The frame 400 may include an overlay representation of the perceived route 402. The perceived route 402 may indicate the upcoming path of the real-world route displayed in the frame 400. In some embodiments, the perceived route 402 itself is not included in the video data, but may be optionally displayed as an icon overlay positioned by the exercise device 104 according to the perceived route data included in the exercise program. Alternatively, the video data may be altered to permanently include the perceived route 402.

The frame 400 may also include a ghost 404A and a ghost 404B (collectively “ghosts 404”). A “ghost” may refer to an icon, indicia or other representation that moves along the perceived route 402 as the user performs the exercise program. The ghosts 404 may represent a relative position on the real-world path relative to the perception of the viewer of the frame 400. The ghosts 404 may be represented by an icon overlaying the video data on the perceived route 402. The icon representing the ghosts 404 may overlay the video data along the perceived route without showing the perceived route 402 on the frame 400.

Locating the ghosts 404 on the video data according to the perceived route data may depict the ghosts 404 as being located on and following the real-world route shown on the frame 400. The ghosts 404 may represent any location of interest on the real-world route.

For example, the ghost 404A may represent a best time that the user previously completed the exercise program. The ghost 404B may represent a location of another person, such as a social acquaintance, the person who captured the video, or any other person, such as a celebrity and/or trainer, for whom information regarding the real-world route or simulated real-world route is known. In some instances, the ghost 404B may represent a person completing the same exercise program at the same time. Alternatively, the ghost 404B may represent available completion data of another person, positioned as if the ghost 404B started the exercise program at the same time as the user. Thus, the ghosts 404 may allow people to virtually race about simulated real-world routes at different times and in different locations. Ghost data and accompanying information may be exchanged between exercise devices via a network such as the network 127 and potentially with assistance from one or more communication devices such as the communication device 132.

The ghosts 404 are shown with identifying labels. More or less information may be shown regarding the ghosts 404. For example, information such as speed; pace; distance from user; whether the user is gaining on, pacing, or falling behind; or the like or any combination thereof may be displayed. Other visual information may be displayed, such as a picture or avatar of the person represented by the ghosts 404. The appearance of the ghosts 404 may also be changed to reflect a preference of the user and/or the person represented by the ghosts 404. For example, the person represented by the ghost 404B may select an avatar to be displayed to users of the exercise program who race the ghost 404B.

In some instances, when the user is ahead of the position of one or more of the ghosts 404, an icon may be displayed at the bottom of the frame 400 indicating that the ghost is “behind” the user. Furthermore, when one or more of the ghosts 404 is ahead of the user to a degree that the ghost is no longer on the perceived route 402 within the frame 400, an icon may be displayed where the perceived route 402 leaves the frame, or the like, indicating that the ghost is farther along the real-world route than can be seen in the frame 400.

In some embodiments, other icons and/or ghosts may be used to represent other information. For example, a ghost may represent a target pace or another goal of the user. Alternately or additionally, icons representing virtual signposts may be placed along the perceived route 402. As used herein, “signpost” may refer to an icon that appears to remain stationary relative to the perceived route 402, similar to a real signpost located along the real-world route. The virtual signposts may include distance-markers, motivational messages, or the like.

The embodiments described herein may physically alter operating parameters of an exercise device, may generate instructions for physically altering operation parameters of an exercise device from location data associated with a real-life route, and/or the like. Alternately or additionally, the embodiments described herein may include the use of a special purpose or general-purpose computer including various computer hardware or software modules, as discussed in greater detail below.

Embodiments described herein may be implemented using computer-readable media for carrying or having computer-executable instructions or data structures stored thereon. Such computer-readable media may be any available media that may be accessed by a general purpose or special purpose computer. By way of example, and not limitation, such computer-readable media may include tangible computer-readable storage media including random-access memory (RAM), read-only memory (ROM), electrically erasable programmable read-only memory (EEPROM), compact disc read-only memory (CD-ROM) or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other storage medium which may be used to carry or store desired program code in the form of computer-executable instructions or data structures and which may be accessed by a general purpose or special purpose computer. Combinations of the above may also be included within the scope of computer-readable media.

Computer-executable instructions include, for example, instructions and data which cause a general purpose computer, special purpose computer, or special purpose processing device to perform a certain function or group of functions. Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.

As used herein, the term “module” or “component” may refer to software objects or routines that execute on the computing system. The different components, modules, engines, and services described herein may be implemented as objects or processes that execute on the computing system (e.g., as separate threads). While the system and methods described herein are preferably implemented in software, implementations in hardware or a combination of software and hardware are also possible and contemplated. In this description, a “computing entity” may be any computing system as previously defined herein, or any module or combination of modulates running on a computing system.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope. 

What is claimed is:
 1. A system comprising: a receiving module for receiving location data associating video frames depicting a real-world route with a topographical location of the real-world route, the video frames having been captured by a video-capturing device while traversing the real-world route; and a conversion module for creating an exercise program comprising: control signals representing changes to be made to one or more operating parameters of an exercise device as the video frames depicting the real-world route are displayed to a user of the exercise device, the control signals based at least in part on the location data, and the changes to the one or more operating parameters corresponding at least in part to one or more aspects of the real-world route; and an icon overlaying the video frames and depicted as being located on the real-world route depicted in the video frames as captured by the video-capturing device while traversing the real-world route.
 2. The system of claim 1, wherein the location data includes global positioning data collected via a satellite navigation system as the video frames were captured while the video-capturing device was traversing the real-world route.
 3. The system of claim 1, wherein: the exercise program further includes environment signals representing one or more target environmental parameters for a location of the exercise device and that cause a change in real-world environmental conditions in a room housing the exercise device; the change in the real-world environmental conditions in the room housing the exercise device is accomplished by one or more of: a heating/cooling system, a humidifier, a dehumidifier, a fan, a mister, and a light; and the target environment parameters correspond at least in part to one or more environmental aspects of the real-world route that were observed as the video frames were captured while the video-capturing device was traversing the real-world route.
 4. The system of claim 1, wherein the icon is a ghost icon that represents a relative position on the real-world route relative to the user of the exercise device and appears to move along the real-world route depicted in the video frames.
 5. The system of claim 4, wherein the ghost icon is depicted with an identifying label that shows information regarding the ghost icon and that is shown as being attached to the ghost icon.
 6. The system of claim 5, wherein the information regarding the ghost icon includes one or more of: a speed of the ghost icon; and a pace of the ghost icon.
 7. The system of claim 1, further comprising a computing device including the receiving module and the conversion module.
 8. The system of claim 1, further comprising a communication device including the receiving module and the conversion module, the communication device for delivering the exercise program to the exercise device by way of a network.
 9. The system of claim 8, further comprising a distribution module for: providing, by way of the network, information about a plurality of exercise programs, including the exercise program; and delivering the exercise program to the exercise device by way of the network in response to the exercise program being selected from the plurality of exercise programs.
 10. The system of claim 1, further comprising the exercise device including the receiving module and the conversion module.
 11. The system of claim 1, wherein the icon is a virtual signpost icon that appears as a real-world signpost located along the real-world route and appears to remain stationary relative to the real-world route depicted in the video frames.
 12. The system of claim 11, wherein the virtual signpost icon displays a marked distance and/or a motivational message.
 13. A communication device comprising: a receiving module for: receiving, by way of a network, video frames depicting a real-world route, the video frames having been captured by a video-capturing device while traversing the real-world route; and receiving, by way of the network, location data associating the video frames with a topographical location of the real-world route; a conversion module for creating an exercise program comprising: the video frames depicting the real-world route; control signals representing changes to be made to one or more operating parameters of an exercise device as the video frames depicting the real-world route are displayed to a user of the exercise device, the control signals based at least in part on the location data, and the changes to the one or more operating parameters corresponding at least in part to one or more aspects of the real-world route; and an icon overlaying the video frames and depicted as being located on the real-world route depicted in the video frames as captured by the video-capturing device while traversing the real-world route; and a distribution module for: delivering, by way of the network, information about a plurality of exercise programs, including the exercise program; and delivering, by way of the network, the exercise program to the exercise device in response to the exercise program being selected from the plurality of exercise programs.
 14. The communication device of claim 13, wherein: the exercise program further includes environment signals representing one or more target environmental parameters for a location of the exercise device and that cause a change in real-world environmental conditions in a room housing the exercise device; the change in the real-world environmental conditions in the room housing the exercise device is accomplished by one or more of: a heating/cooling system, a humidifier, a dehumidifier, a fan, a mister, and a light; and the environment signals correspond at least in part to one or more environmental aspects of the real-world route that were observed as the video frames were captured while the video-capturing device was traversing the real-world route.
 15. The communication device of claim 13, wherein the location data includes global positioning data collected via a global positioning system as the video frames were captured while the video-capturing device was traversing the real-world route.
 16. The communication device of claim 13, wherein the icon is a ghost icon that represents a relative position on the real-world route relative to the user of the exercise device and appears to move along the real-world route depicted in the video frames.
 17. The communication device of claim 16, wherein the ghost icon is depicted with an identifying label that shows information regarding the ghost icon and that is shown as being attached to the ghost icon.
 18. The communication device of claim 17, wherein the information regarding the ghost icon includes one or more of: a speed of the ghost icon; and a pace of the ghost icon.
 19. The communication device of claim 13, wherein the icon is a virtual signpost icon that appears as a real-world signpost located along the real-world route and appears to remain stationary relative to the real-world route depicted in the video frames.
 20. The communication device of claim 19, wherein the virtual signpost icon displays a marked distance and/or a motivational message. 